Designed to imitate the 2011 Virginia quake that rattled the East Coast, the test will occur at 11 a.m. Feb. 19 at the University at Buffalo’s Multidisciplinary Center for Earthquake Engineering Research (MCEER).
Two 14-foot-tall walls – built with materials such as 100-year-old brick – will replicate turn-of-the-century row houses (often called “brownstones”) found in New York.
Researchers will use an earthquake shake table within UB’s earthquake simulation lab to mimic the Virginia temblor as if its epicenter was under the New York region. They will use the test results to calculate estimates for property loss and potential human casualties.
To see a video preview of the test, visit:
Researchers expect the walls to fall apart and crumble to the ground. The test will occur inside a laboratory.
A photo of is available here: http://www.buffalo.edu/news/releases/2013/02/012.html.
While not common, earthquakes periodically hit the New York City region, including a 5.5 magnitude temblor in 1884, according to the U.S. Geological Survey.
“New York City is not a high seismic zone, but the risk there is significant because of the existing infrastructure and large population,” said Juan Aleman, PhD candidate and Fulbright scholar in UB’s School of Engineering and Applied Sciences. “With this test, we hope to learn how buildings will react to a quake similar to the one that struck Virginia in 2011.”
Aleman is working with Andrew Whittaker, MCEER director and professor and chair of UB’s Department of Civil, Structural and Environmental Engineering; and Gilberto Mosqueda, a former UB researcher, who works as an associate professor in structural engineering at the University of California, San Diego.
The upcoming test is collaboration between UB and the International Masonry Institute.
The test will occur at Ketter Hall on UB’s North Campus. Here is a map link: http://www.buffalo.edu/buildings/maps/NorthCampus.pdf
Who to contact:
Media interested in attending the experiment are asked to contact Cory Nealon, UB Office of Communications, at 716-645-4614 or firstname.lastname@example.org.
Cory Nealon | Source: Newswise
Further information: www.buffalo.edu
More articles from Earth Sciences:
Deep-Sea Study Reveals Cause of 2011 Tsunami
06.12.2013 | McGill University
No Undo for Climate Change: Potential Pitfalls of Geoengineering
05.12.2013 | Max-Planck-Institut für Biogeochemie
International team of scientists develops new feedback method for optimizing the laser pulse shapes used in the control of chemical reactions
In many ways, traditional chemical synthesis is similar to cooking. To alter the final product, you can change the ingredients or their ratio, change the method of mixing ingredients, or change the temperature or pressure of the environment of the ingredients.
Like an accomplished chef, chemists have become very skilled ...
A genetic defect protects mice from infection with influenza viruses
A new study published in the scientific journal PLOS Pathogens points out that mice lacking a protein called Tmprss2 are no longer affected by certain flu viruses.
The discovery was made by researchers from the Helmholtz Centre for Infection Research (HZI) in Braunschweig in collaboration with colleagues from Göttingen and ...
The Light: Global study gets underway with online user survey
Light has a fundamental impact on our sense of well-being and performance. In cooperation with Zumtobel, a supplier of lighting solutions, Fraunhofer IAO has launched a global user survey of lighting quality in offices. The objective is to identify the best lighting conditions for a variety of spaces and lighting ...
Quantum entanglement, a perplexing phenomenon of quantum mechanics that Albert Einstein once referred to as “spooky action at a distance,” could be even spookier than Einstein perceived.
Physicists at the University of Washington and Stony Brook University in New York believe the phenomenon might be intrinsically linked with wormholes, hypothetical features of space-time that in popular science fiction can provide a much-faster-than-light shortcut from one part of the universe to another.
But here’s the catch: One couldn’t actually ...
A star is formed when a large cloud of gas and dust condenses and eventually becomes so dense that it collapses into a ball of gas, where the pressure heats the matter, creating a glowing gas ball – a star is born.
New research from the Niels Bohr Institute, among others, shows that a young, newly formed star in the Milky Way had such an explosive growth, that it was initially about 100 times brighter than it is now. The results are published in the scientific journal, Astrophysical Journal Letters.
The young ...
06.12.2013 | Materials Sciences
06.12.2013 | Life Sciences
06.12.2013 | Life Sciences
05.12.2013 | Event News
04.12.2013 | Event News
12.11.2013 | Event News